The role of extracellular calcium (Caex) in modulating keratinocyte differentiation has been well documented, but its role in proliferation has been harder to define due to the confounding effect of terminal differentiation. Because strontium (Sr) does not induce terminal differentiation in murine keratinocytes but does mimic the stimulatory effect of Caex on DNA synthesis in chick fibroblasts, experiments were undertaken to determine if Sr could be used to separate the presumably opposing effects of Caex on the proliferation and differentiation of cultured human keratinocytes. In response to additions of SrCl2, keratinocytes in a serum-free hormone-supplemented basal medium containing 0.03 mM Ca showed a dose-dependent increase in day 7 cell yields. Cell yield in the optimal concentration of SrCl2 (1.8 mM) was approximately twice that obtained in any concentration of CaCl2. Maximally stimulatory additions of CaCl2 varied from 0.05 to 1.8 mM, but 0.03 and 0.05 mM additional CaCl2 always increased cell yield relative to unsupplemented controls. Keratinocytes grown in low levels of CaCl2 or any level of SrCl2 have minimal contact with each other regardless of cell density in contrast to the colonies of tightly apposed and stratified cells grown in 1.8 mM CaCl2. Transmission electron micrographs of vertically sectioned confluent cultures in low or high levels of SrCl2 or in low levels of CaCl2 revealed abundant ribosomes and keratin filaments but no stratification or desmosomes, while cultures in 1.8 mM CaCl2 were stratified with numerous desmosomes. These results suggest that Caex may separately stimulate keratinocyte proliferation and terminal differentiation and that Srex can substitute for Caex in the former but not the latter process.
Calcium-containing crystals and elevated levels of calcium chloride (CaCI,) and lanthanum chloride (LaCI,) have been previously reported to enhance the proliferative activity of cultured fibroblasts. We have investigated the relative mitogenicity of these agents, whether they function via precipitation on the cell surface and whether they interact with one another. Confluent cultures of newborn foreskin fibroblasts provided with fresh medium containing 10% fetal bovine serum (FBS) in the presence of hydroxyapatite (HA), pyrophosphate (PP,), LaCI, (La), or additional CaCI, (Ca) were all stimulated more than control cultures provided with fresh medium and 10% FBS alone as assessed by cell counts 5 days later. Increases in cell yield above the original confluent cell density were 316% for La, 271% for Ca, 189% for HA, 131% for PP,, and 45% for controls. Addition of fresh medium containing 10% FBS and epidermal growth factor or fresh medium containing 20% FBS as additional points of reference yielded increases of 204 and 107%, respectively, over original confluent density. Stimulation induced by La or Ca was significantly greater (P c 0.001) than the stimulations induced by each of the other treatments. The same treatments added to confluent cultures without a change of medium also renewed mitotic activity, with La and Ca again the most mitogenic and approximately doubling the pretreatment cell yields. Cultures incubated in an inverted position to avoid cell contact with precipitates in the medium were also stimulated by La and Ca, but not by HA and PP,. When added to confluent cultures simultaneously supplemented with optimal additional Ca, La decreased Day 5 cell yields in a dose-dependent manner at low concentrations (0.03-0.2 mM) but increased cell yields over those obtained with 0.2 mM LaCI, again in a dose-dependent manner at higher concentrations. Thus, while HA and PP, act via precipitation on the cell surface, the more mitogenic agents La and Ca function in solution and appear to stimulate cell division by different nonadditive mechanisms. These findings suggest multiple mechanisms of membrane participation in mitogen responsiveness and in density-dependent inhibition of growth. [P.S.E.B.M. 1989[P.S.E.B.M. , Vol 1901 ensity-dependent inhibition of growth is a characteristic behavior of cultured diploid fibro-D blasts that is altered by cellular aging in vitro ( I, 2) but not expressed by cultured malignant or malig- nantly transformed cells (3, 4). Hence, although its mechanism is poorly understood, density-dependent growth inhibition can be assumed to reflect important aspects of cellular growth regulation.Recent studies with normal human fibroblasts show that elevating extracellular calcium concentration 'This work was supported by the Agricultural Research Service
Elevating the level of extracellular calcium (CaEx2+) increases the saturation density achieved by the normal human diploid cell line, WI-38, but does not change the growth rate. Day 7 cell yields remain unchanged when [CaEx2+] is between 0.5 mM and 3.0 mM, decrease when [CaEx2+] less than 0.5 mM, and increase when [CaEx2+] greater than 3.0 mM. Combining hydrocortisone with additional CaCl2 results in an additive effect on the saturation density relative to that obtained with each treatment separately. The stimulatory effect of elevated [CaCl2] is independent of serum concentration but is lost when WI-38 cells are grown in conditioned medium. Stimulation is recovered when conditioned medium is diluted with serum-free medium. In the case of young cultures grown in conditioned medium, stimulation can also be recovered when higher than usual levels of additional CaCl2 are used (2-3 mM). A glutamine supplementation to the conditioned medium potentiates cell response to elevated [CaCl2]. These results indicate that the loss of an enhanced saturation density when cells are grown in conditioned medium is not due to serum depletion but is more likely the effect of metabolites and/or nutrient depletion. When older or less vigorously growing cultures are grown in conditioned medium, additions of up to 3 mM CaCl2 only lead to inhibition, suggesting an age-related change in proliferative regulation. Elevated levels of CaEx2+ also enhance the proliferative response of quiescent monolayers to serum stimulation. This finding, along with the increase in saturation density of Ca2+-treated cultures, suggests that an elevated level of CaEx2+ affects cell entry into and exit from quiescence brought on by density-dependent inhibition.
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